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Title Preferences for cancer investigation: a vignette-based study of primary care attenders Authors Jonathan Banks, Sandra Hollinghurst, Lin Bigwood, Tim J Peters, Fiona M Walter, Willie Hamilton Corresponding author Jonathan Banks PhD School of Social & Community Medicine University of Bristol, Canynge Hall, 39 Whatley Road Bristol BS8 2PS Tel: 0117 92 87230 E Mail: [email protected] Lin Bigwood MA & Sandra Hollinghurst PhD School of Social & Community Medicine University of Bristol Canynge Hall, 39 Whatley Road Bristol BS8 2PS Professor Tim J Peters PhD School of Clinical Sciences 69 St Michael's Hill Bristol, BS2 8DZ Fiona M Walter MD The Primary Care Unit, Department of Public Health & Primary Care University of Cambridge Strangeways Research Laboratory, Wort's Causeway Cambridge, CB1 8RN Professor William Hamilton MD University of Exeter College House, St Luke’s Campus Exeter, EX2 4TE 1 Abstract Background The UK lags behind many European and developed countries in terms of cancer survival. Initiatives to address this disparity have focused on barriers to presentation, symptom recognition and referral for specialist investigation. The threshold risk of cancer in primary care warranting specialist investigation has come under particular scrutiny, though UK population preferences for referral thresholds have not been studied. We investigated preferences for diagnostic testing for colorectal, lung, and pancreatic cancer in a large sample of primary care attenders. Methods Electronic survey of general practice attenders aged ≥40 using vignette-based questionnaires. The vignettes outlined: the symptoms potentially representing lung, pancreatic, or colorectal cancer; the risk posed by the symptoms (1, 2, 5 & 10%); and the testing process. The outcome was whether or not respondents indicated that they would opt for cancer testing on each of a maximum of three vignettes – one for each cancer with risk allocated randomly. The main analysis used logistic regression. Findings 3,469 participants completed 6,930 vignettes, with 3,052 (88%) opting for investigation. A higher risk of cancer was weakly associated with increased opting for investigation: odds ratio for a one percentage point increase in cancer risk 1·02 (95% confidence interval 0·99 to 1·06; p=0·189), though in the case of colorectal cancer there was a strong association (OR 1·08; 95% CI: 1·03 to 1·13; p=0·001). In multivariable analysis, age predicted opting for investigation, with ages 60-69 higher, and age ≥70 lower, against reference ages of 40-59 (p=0·035 colorectal; p<0·0001 pancreatic and lung). Other variables associated with increased likelihood of opting for investigation were: shorter travel times to testing centre (colorectal and lung), a family history of cancer (colorectal and lung), and higher household income (colorectal and pancreatic). Interpretation Participants in this sample expressed a clear preference for testing at all risk levels, including 1%. This shows an appetite for testing at risk levels well below current UK guidelines and contributes to the ongoing design of cancer pathways, particularly in primary care. The public engagement with this study should encourage GPs to involve patients in decision making around risk, referral and investigation. Funded by the National Institute for Health Research (NIHR) Programme Grants for Applied Research programme, RP-PG-0608-10045. 2 Preferences for cancer investigation: a vignette-based study of primary care attenders Introduction Over one in three people in the UK will develop cancer during their lifetime. Although cancer mortality in the UK has improved recently, it still lags behind average European figures.1 A number of initiatives have sought to address this, including the Cancer Reform Strategy and the establishment of the National Awareness and Early Diagnosis Initiative (NAEDI).2 Earlier diagnosis is considered to be one of the main ways to improve UK survival, particularly by refining selection of patients for cancer investigation.3 Almost 90% of patients with cancer are diagnosed after experiencing symptoms, and most of these patients present to primary care.4 Selection of patients for investigation is not straightforward: over-investigation has clinical and financial costs, and underinvestigation risks delay in diagnosis, with clinical and medico-legal costs. This selection process is undertaken by clinicians, who have largely determined provision of cancer diagnostic services. However, other groups have a legitimate interest in this decision: providers of cancer diagnostic services, government, the taxpayer, insurers, and, most importantly, patients. Most common symptoms of cancer may also represent benign disease. In deciding whether to investigate for possible cancer, General Practitioners (GPs) use their experience and national guidelines, especially the highly influential National Institute for Health and Care Excellence (NICE) guidance issued in 2005.5 This guidance also underpins the provision of two-week wait clinics, which promise that patients are seen within that time. NICE guidance describes symptoms, or combinations of symptoms and signs, deemed worthy of investigation. By implication, the likelihood of the patient having cancer is high enough to justify investigation, though no explicit risk threshold warranting investigation for cancer has been published in UK or any other national guidance.6 The percentage of patients referred to two-week wait clinics who transpire to have cancer varies across cancer sites, geographical areas, and GPs.7 However, only a quarter of cancers are diagnosed through these clinics, with other patients presenting as emergencies or being referred to other specialist services.8, 9 Recent research in primary care has estimated the risk of cancer for many symptoms, with several symptoms recommended by NICE having a high likelihood of cancer: few of the NICE recommendations equate to risks below 5%.10, 11 NICE referral guidance strongly recommends involving the patient in making the decision to be tested,5 though there has been very little research on patient preferences in the diagnostic sphere. Previous research has focussed on treatment or follow-up options,12 and patient preferences for screening,13 predictive investigation,14 or sharing risk information.15 Patients certainly fear cancer – ahead of knife crime, Alzheimer's disease, and job loss, for example. Nevertheless, it is unknown to 3 what extent patients would choose investigation for cancer when provided with the relevant information about cancer risk, the details of investigation, and possible outcomes. We addressed this issue in the study reported here. Method This was a vignette-based survey to determine the likelihood that participants would choose to be tested for cancer at various levels of risk. Three contrasting cancers were chosen - colorectal, lung, and pancreatic – as they differ in terms of symptoms, type of test, treatment, and prognosis. The main question of what proportion of the population would opt for investigation at each risk level was addressed using a simple ‘yes/no’ alternative. The survey was administered using an electronic touch screen tablet computer (iPad). Survey design We developed twelve separate vignettes (excerpts in Table 1). These were refined in two rounds of cognitive interviewing using the verbal probing method16 with 18 members of 3 GP practice patient groups: participants (n=13) were asked for their understanding of each question and information screen. Responses were recorded systematically and collated. Following redesign, the questionnaire was tested again (n=5) and this was followed by a full week of piloting. There were four vignettes for each of the three cancers, portraying different risk levels (1, 2, 5, and 10%). The content was informed by NICE guidelines, qualitative interviews with patients referred for diagnostic tests for the three cancers,17 and clinical experience.18-20 Each contained a description of symptoms, the risk that these might indicate cancer (both numerically and pictorially), information about the relevant diagnostic test, likely treatment, possible alternative diagnoses, and an indication of the prognosis, if cancer were identified. The vignette culminated in a brief summary of information and asked the respondent whether they would opt for diagnostic testing at that point, or defer or avoid investigation (the exact wording being ‘YES – I would choose to be tested’ or NO - I would not want to be tested now’). After this choice, participants were asked for the main reason for their decision, using a list of options that were informed by qualitative interviews,17 questionnaires previously used in cancer research21 and the cognitive interviewing phase. Participants could complete up to three vignettes. The first vignette was randomly generated from all 12 possibilities, the second from the two remaining cancers (eight possibilities), and the third from the remaining cancer (four possibilities). We also collected participant characteristics, including age, sex, income, education, employment status, ethnicity, experience of cancer, and convenience of the nearest main hospital. Participants Twenty-six general practices in three areas of England (Bristol & South Gloucestershire, Devon, and the East of England) were recruited to include a broad range of urban and rural locations and varying 4 levels of socio-economic status. The practices had a mean list size of 11,615 patients (range 4,155 to 19,666) compared to an England mean of 6,919; their mean Index of Multiple Deprivation score was 18·2 (4·0-36·6) with an England mean of 21·5; and mean percentage of non-white British ethnicity of 4·7% (0·7-12·8) compared to an England and Wales figure of 12·1% (means from National Public Health Observatory 2011, apart from ethnicity which is from the Office of National Statistics 2009). In these practices, researchers in general practice waiting areas recruited attenders aged ≥40 at different times of the day and week between December 2011 and September 2012. We conducted a test-retest exercise in one additional practice using 48 similar volunteers who agreed to return two weeks later, to complete identical vignettes to their first exercise. These participants were offered £10 shopping vouchers. Analysis In addition to descriptive statistics, for the main question – whether or not to be tested – logistic regression was used, with opting for investigation as the outcome variable. The explanatory variables were cancer site, risk level (as a continuous variable), age group, sex, ethnicity, income band, education, employment, previous diagnosis of cancer, cancer diagnosis in a family member or close friend, convenience of hospital, and travel time to hospital. This analysis used only the first completed vignette from each participant, since this was available for all participants and thus avoided possible differential selection bias for subsequent vignettes. Separate models were developed for each cancer, using all (first, second or third) responses for that cancer. As participants completing multiple vignettes always had a different cancer for the later vignettes, concerns about selection bias in the analysis of each cancer separately were eliminated. Initially, each possible explanatory variable entered univariable analysis to establish the strength of the relationship between it and opting for investigation, and those with a p-value<0·2 were retained for multivariable analysis. The first multivariable model contained only those variables with a univariable p-value<0·05; we then added the other variables sequentially, repeating the process until only variables with p<0·05 were present, after adjusting for all other variables in the model. A supplementary analysis used k-fold cross validation with risk level as the only predictor variable in the base model and all four of the other explanatory variables in Table 4 as additional predictors. We tested these sequentially, omitting variables in turn that did not appear to contribute to the model. We considered the impact of missing data by omitting from the regression models any variables with more than a very small percentage of missing values. We used intracluster correlation coefficients to investigate the degree of clustering of the outcome variable across the 26 practices and the six researchers involved in data collection. Analysis used Stata software (versions 12 & 13). 5 The test-retest analysis was undertaken on the first vignettes and used percentage comparisons for participant characteristics and Kappa statistics for the vignette components. Sample size We estimated 80% of participants given a 10% risk vignette would opt for investigation, and 60% of those at the 1% risk would do so. Using a two-sided 5% alpha and 90% power, this would require 119 participants in each group, or 1428 in total. In practice, the study was extremely popular, recruiting at a much higher rate than expected: as our estimated effect sizes were very uncertain, we continued the study to use our full researcher time. Ethics approval Ethics approval was given by NRES Committee South West – Southmead (ref 11/SW/0055). Role of the funding source This paper presents independent research funded by the National Institute for Health Research (NIHR) Programme Grants for Applied Research programme, RP-PG-0608-10045. The views expressed are those of the authors and not necessarily those of the NHS, the NIHR or the Department of Health. The funders of this study had no role in: study design; data collection, analysis, and interpretation; or the writing of this research paper. The corresponding author had full access to all data and final responsibility for the decision to submit for publication. Results A total of 3,469 participants took part between 06-12-2011 and 01-08-2012, completing 6,930 vignettes; 1415 (29%) declined to participate. The characteristics of the participants are shown in Table 2. The age/sex profile of responders is similar to that of the consulting population in England,22 though compared with the population of England as a whole the sample was low on men aged 40-59 (17% versus 27% ), high on women aged 60-69 (15% versus 11%), and high on all aged 70 and over (29% versus 24%).23 The respondents were largely white British, nearly half were retired, and 15% had previously been diagnosed with cancer, which compares with an estimate of 13% of the over-65 UK population.24 Missing data were minimal; most categories were less than 3% with the only exception being income at 15%. Table 3 gives the proportion of respondents who indicated that they would opt for investigation, given the scenario presented to them. Overall, 88% of participants opted for investigation; this was slightly lower in the lowest risk (1%) group and higher in the highest risk (10%) group, but the difference was small and largely explained by a risk gradient in colorectal cancer. This pattern was consistent across responses to the first, second, and third vignettes. The results of the logistic regression analysis, combining all three cancers and controlling for participant characteristics, confirmed these findings. The overall odds ratio (OR) for a one percentage point increase in risk was 1·02 (95% CI: 0·998 to 1·06; p=0·189): participants were, in 6 general, only slightly more likely to opt for investigation the higher the risk that the symptoms indicated cancer. For lung and pancreatic cancer, compared with colorectal, the odds ratios were 2·66 (95% CI: 1·99 to 3·56) and 1·96 (95% CI: 1·48 to 2·60) respectively, indicating that participants were more likely to opt for investigation for lung and pancreatic cancers than for colorectal cancer. There was no evidence of an overall interaction between risk and cancer site (p value = 0·183) but the models for the individual cancers (Table 4) indicate that in the case of colorectal cancer risk did have an effect on whether to opt for investigation (OR 1·08; 95% CI:1·03 to 1·13; p=0.001). Age appears in all three models, with a similar influence: those aged 60-69 were more likely to opt for investigation than those aged 40-59, and those in the oldest group (70+) least likely to opt for investigation. Further investigation into whether attitude to risk was affected by age revealed weak evidence of a difference overall (p-value of interaction between risk and age 0·10), with notable variation across the different cancers. For instance, in colorectal and pancreatic cancers, when controlling for all other factors, participants in the youngest age group (40-59) were more likely to opt for investigation the higher the risk (OR 1·07; 95% CI: 1·01 to 1·13 for colorectal and OR 1·10; 95% CI: 1·01 to 1·17 for pancreatic). Conversely, participants in the oldest group (70+) were less likely to opt for investigation the higher the risk for lung and pancreatic cancers (OR 0·96 95%; CI: 0·88 to 1·04 for lung and OR 0·93; 95% CI: 0·87 to 1·01 for pancreatic), though the latter confidence intervals were wide, and include the null value. Other variables associated with increased likelihood of opting for investigation were: shorter travel times to testing centre (colorectal and lung), a family history of cancer (colorectal and lung), and higher household income (colorectal and pancreatic). The k-fold cross validation results for all three cancer sites produced final models including the same variables as those in the original models, with almost identical regression coefficients (not shown, but available from authors). Table 5 shows the distribution of participants’ responses for each of the variables identified in the logistic regression. We examined the potential bias of missing data in relation to income by omitting the variable from the two final models in Table 4 with almost identical results for risk level and the other variables. We found negligible intracluster correlation of the preference for investigation by general practice and by researcher for all vignettes, and for each cancer site separately. The main reasons cited by participants (Table 6) opting for investigation in vignette 1 were: ‘peace of mind’ (41%), ‘early detection’ (39%), and ‘family history’ (10%), with minimal variation across the three cancers. The main reasons cited by those choosing not to be investigated were: ‘low risk of cancer’ (26%), ‘low risk at my age’ (19%), and ‘rather not know’ (13%). There was much greater variation across the cancers in the no responses, with much higher proportions citing ‘unpleasant 7 test’ and ‘harmful test’ for colorectal (19% and 11% respectively) compared with lung and pancreatic, which was ≤3% in both categories. Test-retest The primary research question of whether the participant chose to undergo diagnostic tests for cancer showed excellent test-retest consistency, with a Kappa statistic of 0·878 (>0·75=excellent). Participants’ reasons for their choice produced Kappa statistics of 0·584 (yes) and 0·667 (no), which are both in the fair to good range (0·4-0·75).25 The social and economic status data demonstrated reliable test-retest consistency: six out of 10 questions returned >90% agreement, three were between 80% and 89% and the lowest (hospital travel time) was 69%. Discussion To our knowledge this is the first study of public preferences for cancer investigation. It showed that 88% of participants would opt for investigation given a realistic scenario of symptoms, along with the risk of cancer these symptoms posed, plus a description of the relevant investigation and likely outcomes. Despite the strong preference for testing, a risk gradient was still evident. Although this risk gradient was identified in the analysis incorporating all three cancers, it was primarily driven by the colorectal findings, where participants appeared to make a trade-off between the invasiveness of the colonoscopy and the risk of cancer. Age was also influential, with the preference for investigation highest in the age group 60-69 and lowest in those aged 70+. The main results The most striking finding was the appetite for testing. This far exceeds what is actually being offered in the NHS, and bears comparison with Slevin et al who found that cancer patients were more likely than clinicians to choose chemotherapy, even when benefits were minimal.26 It is possible participants simply opted for a free test, with some evidence for this in the lack of differentiated responses at low and high risks for lung and pancreatic cancer; this could indicate that the vignettes were insufficiently sensitive to different risk levels. However, the demonstrable differences by risk gradient for colorectal cancer and by age group suggest that this was a considered response. Our four examples for colorectal cancer all met current NICE guidance (because of the six weeks of diarrhoea), though there are many low-risk (1-5%) symptoms that do not meet NICE guidance.10, 11 For lung the position is similar, in that persistent cough (defined as three weeks or greater) is recommended by NICE for a chest X-ray. Again, many symptoms of lung cancer fall into the 1-5% bracket, but only meet NICE recommendations if present for three weeks.5, 19, 27 It is debatable if any of the pancreatic scenarios used in this study meet current NICE guidance (which largely concentrates on jaundice). Even with these caveats, comparing most patients opting for investigation at even a 1% risk of cancer with a conversion rate of 11%7 in the two-week clinics 8 leaves a considerable gap. Using the 11% figure is a little misleading, as an average conversion rate means that some patients whose risk is below that figure have been selected for investigation. Nonetheless, the current (unpublished) threshold risk figure for investigation of possible cancer must be well in excess of 1%. The survey is also instructive about the referral process and the GP-patient relationship. NICE guidelines, as well as giving referral guidance, emphasise the value and importance of including the patient in the decision-making process for referral and diagnostic testing for cancer – a recognition that effective communication between GP and patient is a key dimension of an appropriate referral.28 The way that participants engaged with this study, the subtle variations in participant preferences, and the high participant numbers, suggest that GPs can have greater confidence in engaging in a dialogue with patients about the meaning of symptoms and the risk of cancer. We know that GPs can underestimate the degree to which patients want information and involvement around decision-making29 and that decisions are sometimes made on a perception of patient preference,30 but our data and experience show there is a willingness within a significant proportion of the population to think about symptom meaning, personal risk and the possibility of cancer. It is this kind of internal dialogue that could be used in the consulting room and turn aspirations about patient involvement into a reality. Our experience shows that ‘fear of cancer’ does not necessarily translate into a fear of talking about cancer. Strengths and weaknesses The use of hypothetical vignettes has methodological strengths and weaknesses. Much of the debate around their use centres on the degree to which responses can be used as accurate measures of views and behaviour, with the correlation between vignette response and actual behaviour being questioned.31 Conversely, several studies have demonstrated that vignette responses are useful indicators of behaviour and compare favourably with other methods of assessing preferences and intentions e.g., Peabody and colleagues.32 The method has been widely used in the investigation of medical choice and judgement e.g., Jiwa and colleagues.33 Many of the participants had not experienced referral for cancer testing and the vignettes provided a means of eliciting preferences in the absence of direct experience. Any questionnaire survey is only useful if the questions are realistic, and the responses thoughtful. We tried to maximise realism in the vignettes, and to make the percentage risk understandable by presenting it numerically and pictorially, using suggestions from our two rounds of cognitive interviewing. Whether the overall high level of opting for investigation was driven by the symptom burden (which worsened with higher risk levels) or by the risk level itself, or by the combination, we cannot know, though the last of these interpretations appears closest to clinical reality. We were 9 realistic in our description of the three first-line investigations (colonoscopy, chest X-ray and CT scanning), including their requirements and possible hazards (largely relevant to colonoscopy with its need for bowel preparation and the very small risk of perforation). Since the study began, the SIGGAR study34 has suggested CT colonography may be as accurate as colonoscopy: it is possible that more participants would have opted for investigation had this been available. We made it clear that earlier diagnosis may not reduce the chance of death from lung and pancreatic cancers, emphasising that most patients would die of their disease, though prompt diagnosis could allow benefit from palliative care. As to the reliability of the responses, the test-retest analyses demonstrated consistent responses. We would also point to the responses given around the reasons for choice as indicating that participants responded reflectively; the subtle variations around the type of test, the risk and the age of respondents demonstrated an engagement with the differing components of the vignette. This was a large study (which greatly exceeded its recruitment targets as the format proved particularly popular with participants) which recruited from urban/rural and wealthy/deprived locations. A recruitment rate of 71% is good for a questionnaire survey. Although our target population was the general UK population susceptible to cancer (adults ≥40) we made a pragmatic decision to recruit from general practice waiting areas. This enabled us to access a large group of people face-to-face about a sensitive health-related subject; moreover, a health care setting provided the time, space and privacy for respondents to complete the questionnaire thoughtfully. There is little published data on the demographics of the primary care attending population. The proportion with a past history of cancer in our sample (15%) is similar to the estimated proportion in the UK population of >65s (13%), and as our sample over-represented >70s the figures may be very similar. This was not the case for ethnicity, where the non-white proportion was clearly smaller. It remains that the small number of non-white individuals in our study means that the effect of any ethnic variation is beyond the scope of this study. Implications for policy and practice There is a large disparity between NICE recommendations and NHS provision in terms of cancer diagnostic pathways, and patient preferences as elicited in this sample – which we recognise underrepresents non-white people. This should influence the ongoing revision of NICE guidance. In terms of clinical practice our findings can also provide a springboard for thinking about the referral decision-making. If more patients can be drawn into a full dialogue about preference, risk and decision-making with their GP then this could go some way toward creating a more effective referral pathway from primary care. 10 Contributors JB, LB, WH, SH, TJP and FW had roles in the design, conduct and management of the study. JB, SH, WH and TJP had roles in the analysis and interpretation of the data. JB, LB, SH and WH contributed to the first drafts of the paper and TJP and FW made critical revisions. The authors fulfil the four criteria for authorship in the ICMJE recommendations. Conflicts of interest WH is the clinical lead for the ongoing revision of the NICE 2005 guidance. His contribution to this article is in a personal capacity, and is not to be interpreted as representing the view of the Guideline Development Group, or of NICE itself. The remaining authors have no conflict of interest relevant to this research paper. Acknowledgments The authors would like to acknowledge the contribution to the research presented in this paper made by the Discovery Programme Steering Committee comprising: Roger Jones (chair); Clare Bankhead; Alison Clutterbuck; Jon Emery; Ardiana Gjini; Joanne Hartland; Maire Justice; Jenny Knowles; Helen Morris; Richard Neal; Peter Rose; Greg Rubin. We would like to thank: Catherine Stabb (Exeter), and East of England Primary Care Research Network, who recruited non-Bristol participants; Helen Morris who coordinated researcher training and project documentation in the East of England; Katie Mills and Nicky Hall who collected qualitative data that informed the vignette development; and Bristol Software Partners who developed the software for the iPad application used to collect data. Study protocol http://www.discovery-programme.org/pdfs/PIVOT%20protocol%20version%201%2001.11.2010.pdf 11 Panel: Research in context Systematic review We searched the background literature for this study using OvidSP between 21.11.2011 and 12.12.2012 using the following MeSH terms ‘patient preference’, ‘decision making’, ‘cancer’, ‘primary health care’, and ‘early diagnosis’. We did not restrict our searches by date. We were unable to find any studies which were directly comparable to our research and, therefore, much of the literature that we have used to situate the rationale and contribution of our study is around the early diagnosis of cancer literature which has developed in recent years. The Discovery team have made a number of contributions to this literature and regularly monitor updates and there have been no further relevant contributions since the original searches. Interpretation Our study showed a clear preference by members of the public for cancer investigations across a range of potential risk levels. Only in the case of colorectal cancer, with its invasive method of testing, was there clear evidence of a gradient linking preference for testing to risk level: even then it remained above 80%. This study brings the voice of the public and patients directly into the ongoing redesign of diagnostic pathways into and out of primary care for cancer in the UK. At the consultation level, the way that people engaged with the survey and the cancer symptom vignettes highlight public willingness to discuss and contemplate risk of cancer and testing potentially allowing a more patient-centred primary care consultation and decision-making process. 12 Table 1. The vignette symptom profiles Colorectal Lung Pancreatic All symptoms are 6 weeks duration 1% 2% Diarrhoea on most days Diarrhoea and stomach pain most days Coughing most days More tired than normal Coughing most days A little out of breath walking up hills You have lost a few pounds In weight 5% 10% Unusually tired for the last six weeks Your GP does a blood test which shows you are anaemic Coughing most days You have coughed blood once Intermittent bleeding from the back passage (rectal bleeding) Your GP does a blood test which shows you are anaemic Coughing most days You have coughed blood a few times You have lost ½ stone in weight 13 Some stomach pain on most days You’ve lost a few pounds in weight Continuous pain in your stomach You’ve lost ½ stone in weight Continuous pain in your stomach You’ve lost ½ stone in weight Continuous pain in your stomach You’ve lost 1 stone in weight Table 2. Participant characteristics (n=number of complete responses) Age group (years) n=3452 Sex n=3461 Annual Income n=2958 Ethnicity n=3453 Education n=3388 Employment n=3446 Cancer diagnosis – self n=3463 Cancer – family/ close friend n=3465 Convenience of hospital n=3461 Travel time to hospital n=3463 40-59 60-69 70+ missing male female missing <£10,000 £10,000 - £25,000 >£25,000 missing White British Other missing None GCSE or equivalent Vocational / ‘A’ level Degree and higher missing Retired Not in paid employment Working part time Working full time missing Yes No missing Yes No missing Very convenient Quite convenient Quite inconvenient Very inconvenient missing <0·5 hour 0·5 – 1 hour >1 hour missing 14 Number 1519 945 988 17 1457 2004 8 720 1166 1072 511 3,096 357 16 1,001 781 850 756 81 1,673 379 607 787 23 522 2941 6 2597 868 4 1,388 1,621 323 129 8 1,759 1,458 246 6 Percentage 44 27 28 <1 42 58 <1 21 34 31 15 89 10 <1 29 23 25 22 2 48 11 17 23 1 15 85 <1 75 25 <1 40 47 9 4 <1 51 42 7 <1 Table 3. Number (%) choosing to be investigated by cancer and risk level Colorectal Lung Pancreatic All three cancers (first vignette only) Risk level Number of responses Number (%) choosing to be tested Number of responses Number (%) choosing to be tested Number of responses Number (%) choosing to be tested Number of responses Number (%) choosing to be tested 1% 572 462 (81%) 581 533 (92%) 582 525 (90%) 898 782 (87%) 2% 569 485 (85%) 571 531 (93%) 580 527 (91%) 838 738 (88%) 5% 580 496 (86%) 589 543 (92%) 572 526 (92%) 873 764 (88%) 10% 570 508 (89%) 582 537 (92%) 582 529 (91%) 860 768 (89%) 2291 1951 (85%) 2323 2144 (92%) 2316 2107 (91%) 3469 3052 (88%) 15 Table 4. Multivariable analysis for each cancer separately Colorectal (colonoscopy) Variable (reference category*) OR 95% CI p-value Risk 1·08 (1·03 to 1·13) 0·0001 Age (40-59)* 1 Lung (chest x-ray) OR 0·0347 95% CI 1 Pancreatic (Ultrasound / CT scan) p-value OR <0·0001 1 95% CI <0·0001 60 – 69 1·29 (0·92 to 1·82) 1·32 (0·86 to 2·03) 2·56 (0·94 to 7·00) 70+ 0·81 (0·59 to 1·11) 0·54 (0·38 to 0·76) 0·35 (0·13 to 0·99) Travel time (<0·5 hr)* 1 0·0004 1 0·0032 0·5 – 1 hr 0·78 (0·59 to 1·03) 0·93 (0·67 to 1·30) >1 hour 0·39 (0·22 to 0·68) 0·41 (0·25 to 0·67) Family cancer (yes)* 1 No 0·72 Household Income (<£10,000)* 1 £10,000 - £25,000 >£25,000 0·0266 (0·53 to 0·96) 1 0·55 0·0006 (0·40 to 0·77) 1 0·0025 0·0001 1·31 0·95 to 1·81) 2·63 (0·97 to 7·16) 1·85 (1·26 to 2·71 3·80 (1·09 to 13·26) 16 p-value Table 5. Number (%) choosing to be investigated by cancer and participant characteristics (variables identified in the multivariable analysis) Colorectal Number of responses Number (%) choosing to be tested Lung Number of responses Pancreatic Number (%) choosing to be tested Number of responses Number (%) choosing to be tested All three cancers (first vignette only) Number Number of (%) responses choosing to be tested Age group (years) 40-59 1,061 917 (86%) 1,076 1,004(93%) 1,083 1,002(93%) 1,519 1,372(90%) 60-69 641 563 (88%) 638 605(95%) 640 601(94%) 945 861(91%) 70+ 580 463 (80%) 598 524 (88%) 583 496 (85%) 988 805 (81%) 2,282 1,943(85%) 2,312 2,133(92%) 2,306 2,099(91%) 3,452 3,038(88%) 1,204 1,052(87%) 1,224 1,143(93%) 1,220 1,126(92%) 1,759 1,586(90%) 0.5 – 1 hour 943 798(85%) 946 874(92%) 943 853(90%) 1,458 1,272(87%) >1 hour 143 101(71%) 150 125(83%) 149 124(83%) 246 189(77%) 2,290 1,951(85%) 2,320 2,142(92%) 2,312 2,103(91%) 3,463 3,047(88%) Travel time to hospital <0.5 hour Cancer – family/close friend Yes 1,739 1,507(87%) 1,778 1,660(93%) 1,769 1,625(92%) 2,597 2,317(89%) No 550 443 (81%) 545 484 (89%) 545 481 (88%) 868 733 (84%) 2,289 1,950(85%) 2,323 2,144(92%) 2,314 2,106(91%) 3,465 3,050(88%) <£10,000 450 357 (79%) 445 403 (91%) 443 376 (85%) 720 595 (83%) £10,000-£25,000 759 642 (85%) 770 715 (93%) 746 685 (92%) 1,166 1,035(89%) >£25,000 806 721 (89%) 806 758 (94%) 825 777 (94%) 1,072 985 (92%) 2,015 1,720(85%) 2,021 1,876(93%) 2,014 1,838(91%) 2,958 2,615(88%) Annual Income 17 Table 6 – Main reasons for choosing yes/no to testing Main reason for answering yes: n (%) All cancers Colorectal Lung Pancreatic 723 (37) 872 (45) 212 (11) 63 (3) 47 (2) 10 (1) 20 (1) 4 (0) 1951 (100) Colorectal 806 890 204 61 58 58 22 45 2144 Lung (38) (42) (10) (3) (3) (3) (1) (2) (100) 832 (39) 877 (42) 195 (9) 66 (3) 62 (3) 43 (2) 21 (1) 11 (1) 2107 (100) Pancreatic 69 60 37 41 66 12 39 11 5 340 66 38 27 18 2 14 3 6 5 179 (37) (21) (15) (10) (1) (8) (2) (3) (3) (100) 57 40 33 26 7 22 3 13 8 209 vignette 1 only peace of mind early detection family history my age puts me at risk no reason given test is straightforward family/friend pressure my lifestyle puts me at risk Total Main reason for answering no: N (%) 1255 (41) 1191 (39) 306 (10) 107 (4) 77 (3) 56 (2) 34 (1) 26 (1) 3052 (100) All cancers low risk of cancer low risk at my age rather not know no reason given unpleasant test early diagnosis would not help harmful test inconvenient difficult to access hospital Total 103 89 59 51 28 37 18 20 12 417 vignette 1 only (25) (21) (14) (12) (7) (9) (4) (5) (3) (100) (20) (18) (11) (12) (19) (4) (11) (3) (1) (100) 18 (27) (19) (16) (12) (3) (11) (1) (6) (4) (100) Lung Pancreatic Colorectal Appendices Table S1 - Vignette content - all symptoms are six week duration 1% - Diarrhoea on most days 2% - 1% - Some stomach pain on most days You’ve lost a few pounds in weight 2% - 1% - Coughing most days More tired than normal 2% - Diarrhoea and stomach pain most days 5% - Unusually tired for the last weeks Your GP does a blood test which shows you are anaemic six 10% - Intermittent bleeding from the back passage (rectal bleeding) Your GP does a blood test which shows you are anaemic Your GP tells you these symptoms could indicate bowel cancer. This type of cancer can respond well to treatment (usually an operation and chemotherapy) and an early diagnosis can improve the outcome. A small number of patients need to have a colostomy (a bag on the abdomen) following treatment. With these symptoms there is a 1%/2%/5%/10% risk of bowel cancer. On average, if 100/50/20/10 people have these symptoms, 1 of them will have cancer. For the other 99/49/19/9, the symptoms will probably be caused by a bowel infection and the symptoms will settle. [Graphical example of risk omitted for space] The best test is a colonoscopy. The day before the test you take a medicine that clears out your bowel. This will usually mean you can’t go to work, or carry out your normal activities as you need to be close to a toilet. The test itself has to be done in a main hospital. You would be given a short sedative; then a doctor puts a long telescope into your rectum to see along your bowel. The test takes about 2 minutes. You would be able to go home later that day, though you would not be able to drive. There is a small risk with this test. In about 1 in a 1000 cases the telescope damages the bowel and the patient needs an operation to repair it. Some stomach pain on most 5% - Continuous pain in your stomach 10% Continuous pain in your days You’ve lost ½ stone in weight stomach You’ve lost ½ a stone in You’ve lost 1 stone in weight weight Your GP tells you these symptoms could indicate pancreas cancer. The pancreas is located behind the stomach. This type of cancer is particularly difficult to treat. Early diagnosis of pancreas cancer does not tend to improve the outcome. With these symptoms there is a 1%/2%/5%/10% risk of pancreas cancer. On average, if 100/50/20/10 people have these symptoms, 1 of them will have cancer. For the other 99/49/19/9 the symptoms will probably be caused by a stomach infection or small ulcer and the symptoms will settle. [Graphical example of risk omitted for space] The best test for pancreas cancer is an ultrasound scan. This will involve a visit to the X-Ray department of your nearest main hospital. A small instrument is pressed to your stomach; it only takes a few minutes and is painless. If this shows abnormalities then you will need to come back for a 2nd test which will usually take place within a few days …. The 2nd test is a CT scan which will involve lying on a couch while a machine shaped like a giant Polo mint passes over your body. The whole procedure takes an hour or so and is also painless. Coughing most days A little out of breath walking up hills You have lost a few pounds in weight 5% - Coughing most days You have coughed blood a few times You have lost ½ stone in weight Your GP tells you these symptoms could indicate lung cancer. This is a difficult cancer treat but current evidence indicates that early diagnosis can improve outcome in some cases. 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